Battery pack

ABSTRACT

Disclosed is a battery pack configured to prevent its components such as a cell assembly from being broken or damaged even though a physical force such as vibrations and impacts is applied to the battery pack. The battery pack includes a cell assembly having a plurality of secondary batteries; an electronic component plate having a plate shape and configured to allow at least one electronic component to be mounted thereon; a lower housing configured to have an inner space with an open top and to accommodate the cell assembly and the electronic component plate therein; and an upper housing configured to cover the open top of the lower housing, wherein coupling members are respectively provided between a lower portion of the cell assembly and the lower housing, between an upper portion of the cell assembly and the electronic component plate, between the electronic component plate and the upper housing, and between the lower housing and the upper housing to couple and fix each other.

This application is a Continuation of U.S. patent application Ser. No.15/117,270, filed on Aug. 8, 2016, which is the National Phase of PCTInternational Application No. PCT/KR2015/001257, filed on Feb. 6, 2015,which claims priority to Korean Patent Application No. 10-2014-0018027filed on Feb. 17, 2014 in the Republic of Korea, the disclosures ofwhich are incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates to a battery pack including at least onesecondary battery, and more particularly, to a battery pack configuredso that its components such as a cell assembly having secondarybatteries may be stably fixed in a housing, and its manufacturingmethod.

BACKGROUND ART

Recently, the demand for portable electronic products such as notebooks,video cameras, cellular phones or the like has rapidly increased, andelectric vehicles, energy storage batteries, robots, satellites havebeen actively developed. For this reason, high-performance secondarybatteries allowing repeated charging and discharging are being activelystudied.

Currently, nickel-cadmium batteries, nickel-metal hydride batteries,nickel-zinc batteries, lithium secondary batteries, and the like areused as commercial secondary batteries. Among them, lithium secondarybatteries have little to no memory effect in comparison withnickel-based secondary batteries, and thus lithium secondary batteriesare gaining a lot of attention for their advantages of free charging ordischarging, low self-discharging, and high energy density.

A lithium secondary battery generally uses lithium oxide andcarbonaceous material as a positive electrode active material andnegative electrode active material, respectively. The lithium secondarybattery includes an electrode assembly in which a positive electrodeplate and a negative electrode plate respectively coated with thepositive electrode active material and the negative electrode activematerial are disposed with a separator being interposed between them,and an exterior, namely a battery case, which seals and accommodates theelectrode assembly together with an electrolyte.

Generally, a lithium secondary battery may be classified into a can-typesecondary battery where the electrode assembly is included in a metalcan and a pouch-type battery where the electrode assembly is included ina pouch of an aluminum laminate sheet, depending on the shape of theexterior.

Recently, secondary batteries are widely used not only for small-sizeddevices such as cellular phones but also middle-sized or large-sizeddevices such as vehicles and power storages. In particular, along withthe exhaustion of carbon energy and the increased interest onenvironments, hybrid electric vehicles and electric vehicles attractattention globally, for example in US, Europe, Japan and Korea. In sucha hybrid electric vehicle or electric vehicle, a battery pack for givinga driving force to a vehicle motor is the most essential part. Since ahybrid electric vehicle or electric vehicle may obtain a driving forceby means of charging and discharging of the battery pack, the hybridelectric vehicle or electric vehicle ensures excellent fuel efficiencyand exhausts no or reduced pollutants, and for this reason, hybridelectric vehicles and electric vehicles are used more and more.

Generally, a battery pack is configured so that electronic componentssuch as a cell assembly which is a secondary battery aggregation havingat least one secondary battery, a battery management system (BMS), acurrent sensor, a relay, a fuse or the like are included in a housing.When configuring such a battery pack, it is very important howcomponents of the battery pack such as a cell assembly are coupled inthe housing.

Further, the battery pack may receive external physical forces such asvibrations and impacts. In particular, a battery pack mounted to anelectric vehicle, including a hybrid vehicle, may be frequently exposedto vibrations and impacts due to the nature of the vehicle, and suchvibrations and impacts are not weak. Therefore, in order to protectvarious components of the battery pack from being broken or damaged dueto external physical forces, every components of the battery pack, suchas a cell assembly, should be stably fixed in the housing without beingmoved.

However, in an existing battery pack, each component such as a cellassembly is not stably coupled in the housing. In particular, in case ofan existing battery pack, a cell assembly is generally fixed in thehousing by securing a lower or side surface of the cell assembly.However, if a side surface is fixed, the space for the fixation isrequired to some extent as a side of the cell assembly, and thus thisconfiguration may not be easily applied to a battery pack having anarrow inner space, and even though this configuration is applied, thebattery pack inevitably has an increased volume. In addition, if a lowersurface is fixed, when an impact or the like is applied to the batterypack, the impact is focused on the fixation portion at the lower surfaceof the cell assembly, and thus the fixation portion may be easilybroken, which can lead to breakage or damage of the cell assembly, andfurther the battery pack.

DISCLOSURE Technical Problem

The present disclosure is designed to solve the problems of the relatedart, and therefore the present disclosure is directed to providing abattery pack configured to prevent its components such as a cellassembly from being broken or damaged even though a physical force suchas vibrations and impacts is applied to the battery pack, itsmanufacturing method, and a vehicle including such a battery pack.

Other objects and advantages of the present disclosure will beunderstood from the following descriptions and become apparent by theembodiments of the present disclosure. In addition, it is understoodthat the objects and advantages of the present disclosure may beimplemented by components defined in the appended claims or theircombinations.

Technical Solution

In one aspect of the present disclosure, there is provided a batterypack, comprising: a cell assembly having a plurality of secondarybatteries; an electronic component plate having a plate shape andconfigured to allow at least one electronic component to be mountedthereon; a lower housing configured to have an inner space with an opentop and to accommodate the cell assembly and the electronic componentplate therein; and an upper housing configured to cover the open top ofthe lower housing, wherein coupling members are respectively providedbetween a lower portion of the cell assembly and the lower housing,between an upper portion of the cell assembly and the electroniccomponent plate, between the electronic component plate and the upperhousing, and between the lower housing and the upper housing to coupleand fix each other.

Preferably, the cell assembly may have an assembly hole formed in alower outer side thereof with a protrusive shape, the lower housing mayhave a lower protrusion provided at a location corresponding to theassembly hole, and the lower protrusion may be inserted into and coupledto the assembly hole to couple and fix a lower portion of the cellassembly to the lower housing.

Also preferably, the lower protrusion may have a thread formed thereon,and a nut may be coupled to the thread of the lower protrusion at anupper portion of the assembly hole.

Also preferably, the cell assembly may have an assembly protrusionprovided thereon, the electronic component plate may have a first platehole provided at a location corresponding to the assembly protrusion,and the assembly protrusion may be inserted into and coupled to thefirst plate hole to couple and fix an upper portion of the cell assemblyto the center plate.

Also preferably, the assembly protrusion may have a thread formedthereon, and a nut may have coupled to the thread of the assemblyprotrusion at an upper portion of the first plate hole.

Also preferably, the electronic component plate may have a second platehole in at least one side thereof, the upper housing may have a firstupper hole formed at a location corresponding to the second plate hole,and a bolt may be inserted into and coupled to the second plate hole andthe first upper hole to couple and fix the electronic component plate tothe upper housing.

Also preferably, threads may be formed at the bolt and the second platehole with shapes corresponding to each other, and the bolt may bescrewed with and fixed to the second plate hole.

Also preferably, the upper housing may have a second upper hole formedin a rim portion thereof, the lower housing may have a lower hole formedin a rim portion thereof, and a bolt may be inserted into and coupled tothe second upper hole and the lower hole to couple and fix the upperhousing to the lower housing.

Also preferably, threads may be formed at the bolt and the second upperhole with shapes corresponding to each other, and the bolt may bescrewed with and fixed to the second upper hole.

Also preferably, the battery pack may further comprise a sealing memberprovided at an upper portion of a side surface of the lower housing.

Also preferably, the electronic component may include at least one of abattery management system (BMS), a current sensor, a relay and a fuse.

In another aspect of the present disclosure, there is also provided avehicle, which comprises the battery pack described above.

Also, in another aspect of the present disclosure, there is alsoprovided a method for manufacturing a battery pack, comprising:preparing a cell assembly having a plurality of secondary batteries, anelectronic component plate on which at least one electronic component ismounted, a lower housing having an empty space therein, and an upperhousing; coupling and fixing an upper portion of the cell assembly tothe electronic component plate; accommodating the cell assembly in theinner space of the lower housing; coupling and fixing a lower portion ofthe cell assembly to the lower housing; coupling and fixing theelectronic component plate to the upper housing; and coupling and fixingthe lower housing to the upper housing.

Advantageous Effects

According to an embodiment of the present disclosure, every component ofa battery pack, such as a cell assembly, may be stably coupled and fixedin a housing.

Therefore, in this embodiment of the present disclosure, even thoughvibrations or impacts are applied to the battery pack, variouscomponents such as the cell assembly may not be easily broken ordamaged.

In particular, according to an embodiment of the present disclosure,since the impact applied to the cell assembly may not be focused on aspecific portion such as the lower surface but be dispersed to variousportions, it is possible to more efficient prevent the cell assemblyfrom being damaged or broken.

In addition, according to an embodiment of the present disclosure, sincethe cell assembly and electronic components may be stably fixed andcoupled without needing much additional space for the coupling, thebattery pack may have a compact design.

Further, the present disclosure may be more effectively applied to abattery pack for an electric vehicle, which may be exposed to vibrationsand impacts more frequently.

In addition, according to an embodiment of the present disclosure, thecell assembly and electronic components may be stably fixed, and alsothe battery pack may be assembled easily without any complicatedprocess.

DESCRIPTION OF DRAWINGS

The accompanying drawings illustrate preferred embodiments of thepresent disclosure and, together with the foregoing disclosure, serve toprovide further understanding of the technical spirit of the presentdisclosure. However, the present disclosure is not to be construed asbeing limited to the drawings.

FIG. 1 is an exploded perspective view schematically showing a batterypack according to an embodiment of the present disclosure.

FIG. 2 is an exploded perspective view schematically showing only a cellassembly and an electronic component plate, employed at the battery packof FIG. 1.

FIG. 3 is a diagram showing the battery pack of FIG. 1, except for anupper housing and an electronic component plate, observed from theabove.

FIG. 4 is a diagram showing the battery pack of FIG. 1, except for anupper housing, observed from the above.

FIG. 5 is a schematic flowchart for illustrating a method formanufacturing a battery pack according to an embodiment of the presentdisclosure.

BEST MODE

Hereinafter, preferred embodiments of the present disclosure will bedescribed in detail with reference to the accompanying drawings. Priorto the description, it should be understood that the terms used in thespecification and the appended claims should not be construed as limitedto general and dictionary meanings, but interpreted based on themeanings and concepts corresponding to technical aspects of the presentdisclosure on the basis of the principle that the inventor is allowed todefine terms appropriately for the best explanation.

Therefore, the description proposed herein is just a preferable examplefor the purpose of illustrations only, not intended to limit the scopeof the disclosure, so it should be understood that other equivalents andmodifications could be made thereto without departing from the scope ofthe disclosure.

FIG. 1 is an exploded perspective view schematically showing a batterypack according to an embodiment of the present disclosure.

Referring to FIG. 1, a battery pack according to the present disclosureincludes a cell assembly 100, an electronic component plate 200, a lowerhousing 300 and an upper housing 400.

The cell assembly 100 has at least one secondary battery. In particular,in the battery pack, the cell assembly 100 may be a secondary batteryaggregation having a plurality of secondary batteries. Here, theplurality of secondary batteries may be pouch-type secondary batteries.In this case, the pouch-type secondary batteries may be configured to bestacked in one direction, for example in a vertical direction.

Meanwhile, the cell assembly 100 may include a stacking frame forstacking a plurality of secondary batteries. The stacking frame is acomponent used for stacking secondary batteries, and the stacking framemay hold secondary batteries to prevent shaking of the secondarybatteries, and many stacking frames may be stacked with each other toguide assembling of secondary batteries. The stacking frame may also becalled with various terms, for example a cartridge, and may have arectangular ring shape with a hollow center. In this case, four edges ofthe stacking frame may be located at the outer circumference of apouch-type secondary battery, respectively.

The electronic component plate 200 may be configured with a plate shapehaving broad surfaces at its upper and lower portions. In addition, onthe broad upper surface of the electronic component plate 200,electronic components may be mounted. The configuration of theelectronic component plate 200 will be described in more detail withreference to FIG. 2.

FIG. 2 is an exploded perspective view schematically showing only thecell assembly 100 and the electronic component plate 200, employed atthe battery pack of FIG. 1.

As shown in FIG. 2, at least one electronic component may be mounted atan upper portion of the electronic component plate 200. Here, theelectronic component mounted on the electronic component plate 200 mayinclude at least one of a battery management system (BMS) 201, a currentsensor 202, a relay 203 and a fuse 204.

Here, the BMS 201 means a battery management device for controllingcharging/discharging operations of the battery pack as a whole, and theBMS is commonly included in a battery pack.

In addition, the current sensor 202 is a component for sensing acharge/discharge current of the battery pack, and the relay 203 is aswitching component for selectively opening or closing acharge/discharge path on which a charge/discharge current of the batterypack flows. In addition, the fuse 204 is provided on thecharge/discharge path of the battery pack and is fused off to cut theflow of the charge/discharge current when an abnormal situation occursat the battery pack. The current sensor, the relay and the fuse mayexchange data with the BMS and be controlled by the BMS.

The BMS, the current sensor, the relay and the fuse are well known tothose skilled in the art, and thus they are not described in detailhere.

At the electronic component plate 200, at least one bus bar may bemounted in addition to the electronic components. In addition, theelectronic component plate 200 may have a pack terminal exposed out ofthe upper housing. The pack terminal is a terminal used when connectingan external charging/discharging device to the battery pack and mayinclude a positive electrode pack terminal and a negative electrode packterminal. At this time, the bus bar may be used as a charge/dischargepath by connecting an electrode terminal of the cell assembly 100 to thepack terminal, and may electrically connect various electroniccomponents such as a current sensor, a relay and a fuse. In particular,the bus bar may include a positive electrode bus bar and a negativeelectrode bus bar. Here, the positive electrode bus bar may connect apositive electrode terminal of the cell assembly 100 to the positiveelectrode pack terminal, and the negative electrode bus bar may connecta negative electrode terminal of the cell assembly 100 to the negativeelectrode pack terminal. As described above, the bus bar is a componentfor electric connection and thus may be made of a material havingelectric conductivity. In particular, in order to ensure mechanicalstrength to same extent, the bus bar may be formed with a metal materialsuch as copper.

As shown in FIG. 2, the electronic component plate 200 may be located atan upper portion of the cell assembly 100. In this embodiment, the cellassembly 100 and the electronic component plate 200 may be easilyassembled, and the electronic component mounted on the electroniccomponent plate 200 may also be easily connected to the cell assembly100. Moreover, the electronic component mounted on the electroniccomponent plate 200 may be easily separated in an upward direction andmay also be easily mounted from the above, thereby ensuring easyexchange of each electronic component.

The lower housing 300 has an empty space therein, and the inner spacemay be opened at its top. In addition, the lower housing 300 may allowthe cell assembly 100 and the electronic component plate 200 to beaccommodated in the inner space. Since the lower housing 300 may serveas an exterior of the battery pack, the lower housing 300 may givestructural stability to the battery pack and protect components such asthe cell assembly 100 and the electronic component plate 200,accommodated therein, against external physical elements such as impactsand substances.

The upper housing is located at an upper portion of the lower housing300 and may be configured to cover the open top of the lower housing300. In other words, the upper housing may cover the opening of thelower housing 300 so that various components such as the cell assembly100 and the electronic component plate 200 are not exposed out butprotected. Here, the upper housing may have an empty space therein byhaving an upwardly concave shape, and the cell assembly 100 and theelectronic component plate 200 may be at least partially accommodated inthe inner space of the upper housing.

As described above, the battery pack according to the present disclosuremay include the cell assembly 100, the electronic component plate 200,the lower housing 300 and the upper housing, and these components may becoupled and fixed to each other by means of coupling members.

In particular, the lower portion of the cell assembly 100 and the lowerhousing 300 may be coupled and fixed by means of a coupling member, andthe upper portion of the cell assembly 100 and the electronic componentplate 200 may be coupled and fixed by means of another coupling member.In addition, the electronic component plate 200 and the upper housingmay be coupled and fixed by means of still another coupling member, andthe lower housing 300 and the upper housing may also be coupled andfixed by means of further another coupling member. At this time, thecoupling member for coupling components may be integrated to eachcomponent or separately provided from each component.

Preferably, in order to couple and fix the lower portion of the cellassembly 100 and the lower housing 300, as shown in FIG. 2, the cellassembly 100 may have an assembly hole 110 formed in a lower outer sidethereof with a protrusive shape. In addition, the lower housing 300 mayhave a lower protrusion 310 provided on an upper surface thereof at alocation corresponding to the assembly hole 110 of the cell assembly 100to protrude upwards. At this time, a thread may be formed on an outersurface of the lower protrusion. The coupling and fixing configurationbetween the lower portion of the cell assembly 100 and the lower housing300 will be described in more detail with reference to FIG. 3.

FIG. 3 is a diagram showing the battery pack of FIG. 1, except for theupper housing and the electronic component plate 200, observed from theabove.

Referring to FIG. 3, as depicted in a portion A1, a plurality ofassembly holes 110 may be provided at a lower outer side of the cellassembly 100 to protrude in a horizontal direction. In other words, twoassembly holes 110 may be formed to protrude at a left side of the cellassembly 100, and other two assembly holes 110 may be formed to protrudeat a right side of the cell assembly 100. In addition, lower protrusions310 may be formed on the upper surface of the lower housing 300 atlocations corresponding to the four assembly holes 110. Therefore, ifthe cell assembly 100 is accommodated in the inner space of the lowerhousing 300, the four lower protrusions 310 may be respectively insertedinto and coupled through the four assembly holes 110. Due to thecoupling between the assembly holes 110 and the lower protrusions 310,the cell assembly 100 and the lower housing 300 may be coupled and fixedto each other. In particular, in this configuration of the presentdisclosure, it is possible to prevent the cell assembly 100 from movingin a horizontal direction inside the lower housing 300.

Here, a thread may be formed at an outer surface of the lower protrusion310, and a nut N1 may be coupled to the thread of the lower protrusion310 at an upper portion of the assembly hole 110. In other words, in astate where the lower protrusion 310 is inserted into the assembly hole110, the nut N1 may be coupled to the upper portion of the cell assembly100 to fix the cell assembly 100. In this configuration of the presentdisclosure, by means of the nut N1, it is possible to prevent theassembly hole 110 from being separated from the lower protrusion 310 ormoving in an inserted state. Therefore, the cell assembly 100 and thelower housing 300 may be fixed more stably.

Also preferably, in order to couple and fix the upper portion of thecell assembly 100 to the electronic component plate 200, the cellassembly 100 may have an assembly protrusion 120 at an upper portionthereof. The coupling configuration of the cell assembly 100 and theelectronic component plate 200 will be described in more detail withreference to FIGS. 2 to 4.

FIG. 4 is a diagram showing the battery pack of FIG. 1, except for theupper housing, observed from the above.

In more detail, referring to FIGS. 2 to 4, a plurality of assemblyprotrusions 120 are provided at the upper portion of the cell assembly100 and may be formed to protrude upwards. In addition, the electroniccomponent plate 200 may have first plate holes 210 formed at locationscorresponding to the assembly protrusions 120. Therefore, if theelectronic component plate 200 is placed on the upper portion of thecell assembly 100, the plurality of assembly protrusion 120 may beinserted into and coupled to the corresponding first plate holes 210, asindicated in the portion A2 of FIG. 4. Due to the coupling of theassembly protrusion 120 and the first plate hole 210, the cell assembly100 and the electronic component plate 200 may be coupled and fixed toeach other. In particular, in this configuration of the presentdisclosure, it is possible to prevent the electronic component plate 200from moving in a horizontal direction at an upper portion of the cellassembly 100.

Here, a thread may be formed at an outer surface of the assemblyprotrusion 120, and a nut N2 may be coupled to the thread of theassembly protrusion 120 at an upper portion of the first plate hole 210.In other words, in a state where the assembly protrusion 120 is insertedinto the first plate hole 210, the nut N2 may be coupled to the upperportion of the electronic component plate 200 to fix the electroniccomponent plate 200. In this configuration of the present disclosure, bymeans of the nut N2, it is possible to prevent the first plate hole 210of the electronic component plate 200 from being separated from theassembly protrusion 120 or moving in an inserted state. Therefore, thecell assembly 100 and the electronic component plate 200 may be fixedmore stably.

Also preferably, in order to couple and fix the electronic componentplate 200 to the upper housing, the electronic component plate 200 mayhave a second plate hole 220 formed in at least one side thereof. Inaddition, the upper housing may have a first upper hole 410 formed at alocation corresponding to the second plate hole 220.

In more detail, referring to FIGS. 1 to 4, a plurality of second plateholes 220, for example four second plate holes 220, may be formed in theelectronic component plate 200. In addition, in the upper housing, aplurality of first upper holes 410, for example four first upper holes410, may be formed at location s corresponding to the second plate hole220. At this time, the first upper hole 410 may be formed to entire passthrough the upper housing. In this case, a first bolt B1 may be insertedthrough the first upper hole 410 and coupled into the second plate hole220. Therefore, by coupling the first bolt B1 with the first upper hole410 and the second plate hole 220, the electronic component plate 200and the upper housing may be coupled and fixed to each other.

Here, a thread may be formed at an outer surface of the first bolt B1.In addition, in the second plate hole 220, a thread may be formed with ashape corresponding to the thread of the first bolt B1. Therefore, thefirst bolt B1 may be screwed with and fixed to the second plate hole220. In this configuration of the present disclosure, the couplingbetween the first bolt B1 and the second plate hole 220 may be stablymaintained. In addition, since the first bolt B1 may be inserted intothe second plate hole 220 of the electronic component plate 200 throughthe first upper hole 410 at the upper portion of the upper housing, theelectronic component plate 200 and the upper housing may be coupledeasily, and it is not needed to separately couple a nut or the like tothe lower portion of the electronic component plate 200.

Also preferably, in order to couple and fix the upper housing to thelower housing 300, a second upper hole 420 may be formed in a rimportion of the upper housing. In addition, the lower housing 300 mayhave a lower hole 320 formed at a location corresponding to the secondupper hole 420 of the rim portion.

In more detail, referring to FIGS. 1 and 4, a plurality of lower holes320, for example four lower holes 320, may be formed in the lowerhousing 300. In particular, the lower housing 300 may have a lowersurface and side surfaces to form an accommodation space therein and maynot have an upper surface so that its top is opened. At this time, thelower hole 320 may be located at an uppermost portion of the lowerhousing 300, which comes into contact with the upper housing. Theuppermost portion of the lower housing 300 may be regarded as a rimportion where side surfaces are positioned, and the lower hole 320 maybe formed in the rim portion, namely an upper portion of the sidesurface of the lower housing 300, in a downward direction.

The upper housing may have a plurality of second upper holes 420, forexample four second upper holes 420, formed at locations correspondingto the lower holes 320 of the lower housing 300. Therefore, if the upperhousing is sized and shaped similar to the lower housing 300, the secondupper holes 420 may also be formed in a rim portion of the upperhousing.

In this configuration of the lower housing 300 and the upper housing, asecond bolt B2 may be inserted through the second upper hole 420 andcoupled into the lower hole 320. Therefore, by coupling the second boltB2 to the second upper hole 420 and the lower hole 320, the upperhousing and the lower housing 300 may be coupled and fixed to eachother.

Here, a thread may be formed at an outer surface of the second bolt B2.In addition, the second upper hole 420 may also have a thread formedcorresponding to the thread of the second bolt B2. Therefore, the secondbolt B2 may be screwed with and fixed to the second plate hole 220. Inthis configuration of the present disclosure, the coupling between thesecond bolt B2 and the second plate hole 220 may be stably maintained.In addition, since the second bolt B2 is inserted into the lower hole320 through the second upper hole 420 at the upper portion of the upperhousing, the lower housing 300 and the upper housing may be coupledeasily, and it is not needed to separately couple a nut or the like tothe second bolt B2.

Meanwhile, the lower housing 300 and the upper housing may be configuredto have an approximately rectangular shape, when being observed from theabove. At this time, the lower holes 320 and the second upper holes 420may be formed at least in edge portions of the lower housing 300 and theupper housing with a rectangular shape. In this configuration of thepresent disclosure, the coupling between the lower housing 300 and theupper housing may be stably maintained through the entire regions.

Preferably, the battery pack according to the present disclosure mayfurther include a sealing member at an upper portion of the side surfaceof the lower housing 300.

The sealing member may be interposed between the lower housing 300 andthe upper housing to seal the space between the lower housing 300 andthe upper housing. For this, the sealing member may be located at rimportions of the lower housing 300 and the upper housing which come intocontact with each other. In addition, if the lower housing 300 and theupper housing are configured with a rectangular shape, the sealingmember may also have a rectangular ring shape along the rim portions ofthe lower housing 300 and the upper housing.

The sealing member may be made of polymer material with elasticity, forexample rubber, since it is a component for sealing the lower housing300 and the upper housing.

The battery pack according to the present disclosure may be applied to avehicle such as an electric vehicle and a hybrid vehicle. In otherwords, the vehicle according to the present disclosure may include thebattery pack according to the present disclosure as described above. Inparticular, the battery pack for a vehicle may be frequently exposed toexternal physical forces such as vibrations and impacts, and suchvibrations and impacts may be serious. However, in the battery packaccording to the present disclosure, since the lower portion of the cellassembly 100 is coupled and fixed to the lower housing 300, the upperportion of the cell assembly 100 is coupled and fixed to the electroniccomponent plate 200, the electronic component plate 200 is coupled andfixed to the upper housing, and the lower housing 300 is coupled andfixed to the upper housing. Therefore, each component of the batterypack is stably fixed without moving, and thus it is possible toeffectively prevent each component from being broken or damaged due toinertia, vibrations, impacts or the like. In particular, it is possibleto more effectively prevent the cell assembly 100 from being broken, bypreventing a force from being focused to a specific region of the cellassembly 100 in the pack housing.

Hereinafter, a method for manufacturing a battery pack according to anembodiment of the present disclosure will be described in brief.

FIG. 5 is a schematic flowchart for illustrating a method formanufacturing a battery pack according to an embodiment of the presentdisclosure.

As shown in FIG. 5, in the method for manufacturing a battery packaccording to the present disclosure, first, a cell assembly 100 having aplurality of secondary batteries, an electronic component plate 200 onwhich at least one electronic component is mounted, and a lower housing300 and an upper housing having an empty space therein are prepared(S110).

Next, the electronic component plate 200 is placed on the cell assembly100, and the upper portion of the cell assembly 100 is coupled and fixedto the electronic component plate 200 (S120). After that, the cellassembly 100 to which the electronic component plate 200 is coupled isaccommodated in the inner space of the lower housing 300 (S130). Next,the lower portion of the cell assembly 100 is coupled and fixed to thelower housing 300 (S140), and the open top of the lower housing 300 iscovered by the upper housing. After that, the electronic component plate200 is coupled and fixed to the upper housing (S150), and then the lowerhousing 300 is coupled and fixed to the upper housing (S160).

Meanwhile, the process depicted in FIG. 5 is just an example, and thepresent disclosure is not limited thereto. For example, Step S120 may beperformed after Step S140, and Step S150 may be performed after StepS160.

The present disclosure has been described in detail. However, it shouldbe understood that the detailed description and specific examples, whileindicating preferred embodiments of the disclosure, are given by way ofillustration only, since various changes and modifications within thescope of the disclosure will become apparent to those skilled in the artfrom this detailed description.

Meanwhile, when the terms indicating up, down, left and right directionsare used in the specification, it is obvious to those skilled in the artthat these merely represent relative locations for convenience inexplanation and may vary based on a location of an observer or a shapein which an object is placed.

What is claimed is:
 1. A battery pack, comprising: a cell assemblyhaving a plurality of secondary batteries; an electronic component platedirectly placed on an upper portion of the cell assembly and having aplate shape and configured to allow at least one electronic component tobe mounted thereon; a lower housing configured to have an inner spacewith an open top and to accommodate the cell assembly and the electroniccomponent plate in the inner space; and an upper housing configured tocover the open top of the lower housing, wherein coupling members arerespectively provided between a lower portion of the cell assembly andthe lower housing, between the upper portion of the cell assembly andthe electronic component plate, between the electronic component plateand the upper housing, and between the lower housing and the upperhousing to couple and fix each other, wherein the cell assembly has anassembly protrusion provided thereon, the electronic component plate hasa first plate hole provided at a location corresponding to the assemblyprotrusion, and the assembly protrusion is inserted into and coupled tothe first plate hole to couple and fix the upper portion of the cellassembly to the electronic component plate, and wherein an assembly holeprovided at a lower outer side of the cell assembly to protrude in ahorizontal direction, and a lower protrusion is formed on the uppersurface of the lower housing at a location corresponding to the assemblyhole to insert into the assembly hole.
 2. The battery pack according toclaim 1, wherein the lower protrusion is coupled to the assembly hole tocouple and fix a lower portion of the cell assembly to the lowerhousing.
 3. The battery pack according to claim 2, wherein the lowerprotrusion has a thread formed thereon, and a nut is coupled to thethread of the lower protrusion at an upper portion of the assembly hole.4. The battery pack according to claim 1, wherein the assemblyprotrusion has a thread formed thereon, and a nut is coupled to thethread of the assembly protrusion at an upper portion of the first platehole.
 5. The battery pack according to claim 1, wherein the electroniccomponent plate has a second plate hole in at least one side thereof,the upper housing has a first upper hole formed at a locationcorresponding to the second plate hole, and a bolt is inserted into andcoupled to the second plate hole and the first upper hole to couple andfix the electronic component plate to the upper housing.
 6. The batterypack according to claim 5, wherein threads are formed at the bolt andthe second plate hole with shapes corresponding to each other, and thebolt is screwed with and fixed to the second plate hole.
 7. The batterypack according to claim 1, wherein the upper housing has a second upperhole formed in a rim portion thereof, the lower housing has a lower holeformed in a rim portion thereof, and a bolt is inserted into and coupledto the second upper hole and the lower hole to couple and fix the upperhousing to the lower housing.
 8. The battery pack according to claim 7,wherein threads are formed at the bolt and the second upper hole withshapes corresponding to each other, and the bolt is screwed with andfixed to the second upper hole.
 9. The battery pack according to claim1, further comprising: a sealing member provided at an upper portion ofa side surface of the lower housing.
 10. The battery pack according toclaim 1, wherein the electronic component includes at least one of abattery management system (BMS), a current sensor, a relay and a fuse.11. A vehicle, which comprises the battery pack according to claim 1.12. A method for manufacturing a battery pack, comprising: preparing acell assembly having a plurality of secondary batteries, an electroniccomponent plate on which at least one electronic component is mounted, alower housing having an empty inner space therein, and an upper housing;placing the electronic component plate directly on an upper portion ofthe cell assembly and coupling and fixing the upper portion of the cellassembly to the electronic component plate; accommodating the cellassembly and the electronic component plate in the inner space of thelower housing; coupling and fixing a lower portion of the cell assemblyto the lower housing; coupling and fixing the electronic component plateto the upper housing; and coupling and fixing the lower housing to theupper housing, wherein the cell assembly has an assembly protrusionprovided thereon, the electronic component plate has a first plate holeprovided at a location corresponding to the assembly protrusion, and theassembly protrusion is inserted into and coupled to the first plate holeto couple and fix the upper portion of the cell assembly to theelectronic component plate, and wherein an assembly hole provided at alower outer side of the cell assembly to protrude in a horizontaldirection, and a lower protrusion is formed on the upper surface of thelower housing at a location corresponding to the assembly hole to insertinto the assembly hole.